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Contents. 20.1 Complex Functions as Mappings 20.2 Conformal Mappings 20.3 Linear Fractional Transformations 20.4 Schwarz-Christoffel Transformations 20.5 Poisson Integral Formulas 20.6 Applications. 20.1 Complex Functions as Mappings.

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  1. Contents • 20.1 Complex Functions as Mappings • 20.2 Conformal Mappings • 20.3 Linear Fractional Transformations • 20.4 Schwarz-Christoffel Transformations • 20.5 Poisson Integral Formulas • 20.6 Applications

  2. 20.1 Complex Functions as Mappings • IntroductionThe complex function w = f(z) = u(x, y) + iv(x, y) may be considered as the planar transformation. We also call w = f(z) is the image of z under f. See Fig 20.1.

  3. Fig 20.1

  4. Example 1 • Consider the function f(z) = ez. If z = a + it, 0  t  , w = f(z) = eaeit. Thus this is a semicircle with center w = 0 and radius r = ea. If z = t + ib, − t  , w = f(z) = eteib. Thus this is a ray with Arg w = b, |w| = et. See Fig 20.2.

  5. Fig 20.2

  6. Example 2 • The complex function f = 1/z has domain z 0 and

  7. Example 2 (2) • Likewise v(x, y) = b, b  0 can be written asSee Fig 20.3.

  8. Fig 20.3

  9. Translation and Rotation • The function f(z) = z + z0 is interpreted as a translation. The function is interpreted as a rotation. See Fig 20.4.

  10. Example 3 Find a complex function that maps −1  y  1 onto 2  x  4. SolutionSee Fig 20.5. We find that −1  y  1 is first rotated through 90 and shifted 3 units to the right. Thus the mapping is

  11. Fig 20.5

  12. Magnification • A magnification is the function f(z) = z, where  is a fixed positive real number. Note that |w| = |z| = |z|. If g(z) = az + b and then the vector is rotated through 0, magnified by a factor r0, and then translated using b.

  13. Example 4 Find a complex function that maps the disk |z|  1 onto the disk |w – (1 + i)|  ½. Solution Magnified by ½ and translated to 1 + i, we can have the desired function as w = f(z) = ½z + (1 + i).

  14. Power Functions • A complex function f(z) = zwhere  is a fixed positive number, is called a real power function. See Fig 20.6. If z = rei, then w = f(z) = rei.

  15. Example 5 Find a complex function that maps the upper half-plane y 0 onto the wedge 0  Arg w  /4. Solution The upper half-plane can also be described by 0  Arg w  . Thus f(z) = z1/4 will mapthe upper half-plane onto the wedge 0  Arg w  /4.

  16. Successive Mapping • See Fig 20.7. If  = f(z) maps R onto R, and w = g() maps R onto R, w = g(f(z)) maps R onto R.

  17. Fig 20.7

  18. Example 6 Find a complex function that maps 0  y   onto the wedge 0  Arg w  /4. Solution We have shown that f(z) = ezmaps0  y   onto to 0  Arg    and g() =  1/4 maps0  Arg   onto 0  Arg w  /4. Thus the desired mapping is w = g(f(z)) = g(ez) = ez/4.

  19. Example 7 Find a complex function that maps /4  Arg z  3/4 onto the upper half-plane v  0. Solution First rotate /4  Arg z  3/4 by  = f(z) = e-i/4z. Then magnify it by 2, w = g() =  2.Thus the desired mapping is w = g(f(z)) = (e-i/4z)2 = -iz2.

  20. 20.2 Conformal Mappings • Angle –Preserving MappingsA complex mapping w = f(z) defined on a domain D is called conformal at z = z0 in D when f preserves that angle between two curves in D that intersect at z0. See Fig 20.10.

  21. Fig 20.10

  22. Referring to Fig 20.10, we have Likewise

  23. Proof If a curve C in D is defined by z = z(t), then w = f(z(t)) is the image curve in the w-plane. We have If C1 and C2 intersect at z = z0, then THEOREM 20.1 If f(z) is analytic in the domain D and f’(z)  0, then f is conformal at z = z0. Conformal Mapping

  24. THEOREM 20.1 proof Since f (z0)  0, we can use (2) to obtain

  25. Example 1 (a) The analytic function f(z) = ez is conformal at all points, since f (z) = ez is never zero. (b) The analytic function g(z) = z2 is conformal at all points except z = 0, since g(z) = 2z 0, for z  0.

  26. Example 2 • The vertical strip −/2  x  /2 is called the fundamental region of the trigonometric function w = sin z. A vertical line x = a in the interior of the region can be described by z = a + it, −  t  . We find that sin z = sin x cosh y + i cos x sinh yand so u + iv = sin (a + it) = sin a cosh t + i cos a sinh t.

  27. Example 2 (2) Since cosh2t − sinh2t = 1, thenThe image of the vertical line x = a is a hyperbola with  sin a as u-intercepts and since −/2 < a < /2, the hyperbola crosses the u-axis between u = −1 and u = 1. Note if a = −/2, then w = −cosh t, the line x = −/2 is mapped onto the interval (−, −1]. Likewise, the line x = /2 is mapped onto the interval [1, ).

  28. Example 3 The complex function f(z) = z + 1/z is conformal at all points except z = 1 and z = 0. In particular, the function is conformal at all points in the upper half-plane satisfying |z| > 1. If z = rei, then w = rei+ (1/r)e-i, and soNote if r = 1, then v = 0 and u = 2 cos  .Thus the semicircle z = eit, 0  t  , is mapped onto [−2, 2] on the u-axis. If r > 1, the semicircle z = reit, 0  t  , is mapped onto the upper half of the ellipse u2/a2 + v2/b2 = 1, where a = r + 1/r, b = r − 1/r. See Fig 20.12.

  29. Fig 20.12

  30. Example 3 (2) For a fixed value of , the ray tei, for t  1, is mapped to the point u2/cos2−v2/sin2 = 4 in the upper half-plane v  0. This follows from (3) since Since f is conformal for |z| > 1 and a ray  = 0 intersects a circle |z| = r at a right angle, the hyperbolas and ellipses in the w-plane are orthogonal.

  31. Conformal Mappings Using Tables • Conformal mappings are given in Appendix IV. We may use this table to solve the transformations.

  32. Example 4 Use the conformal mappings in Appendix IV to find a conformal mapping between the strip 0  y  2 and the upper half-plane v  0.What is the image of the negative x-axis? Solution From H-2, letting a = 2 then f(z) = ez/2and noting the positions E, D, Eand D. We can map the negative x-axis onto the interval (0, 1) on the u-axis.

  33. Example 5 Use the conformal mappings in Appendix IV to find a conformal mapping between the strip 0  y  2 and the disk |w| 1. What is the image of the negative x-axis? SolutionAppendix IV des not have an entry that maps 0  y  2 directly onto the disk. In Example 4, the strip was mapped onto f(z) = ez/2the upper half-plane, and from C-4, the complex mapping w = (i – )/ (i + ) maps the upper half-plane to the disk |w|  1.

  34. Example 5 (2) Thereforemaps the strip 0  y  2 onto the disk |w| 1. The negative x-axis is first mapped to the interval (0, 1) in the -plane and from the position of points C and C in C-4, this interval is mapped to the circular arc w = ei, 0 <  < /2 in the w-plane.

  35. THEOREM 20.2 If f be an analytic function that maps a domain D onto a domain D. If U is harmonic in D, then the real-valued function u(x, y) = U(f(z)) is harmonic in D. Transformation Theorem for Harmonic Functions

  36. THEOREM 20.2 Proof We will give a special proof for the special case in which D is simply connected. If U has a harmonic conjugate V in D, then H = U + iV is analytic in D, and so the composite function H(f(z)) = U(f(z)) + iV(f(z)) is analytic in D. It follow that the real part U(f(z)) is harmonic in D.

  37. Solving Dirichlet Problems Using Conformal Mapping • Solving Dirichlet Problems Using Conformal Mapping • Find a conformal mapping w = f(z) that transform s the original region R onto the image R. The region R may be a region for which many explicit solutions to Dirichlet problems are known. • Transfer the boundary conditions from the R to the boundary conditions of R. The value of u at a boundary point  of R is assigned as the value of U at the corresponding boundary point f().

  38. Fig 20.13

  39. Solve the Dirichlet problem in R. The solution may be apparent from the simplicity of the problem in R or may be found using Fourier or integral transform methods. • The solution to the original Dirichlet problems is u(x, y) = U(f(z)).

  40. Example 6 The function U(u, v) = (1/) Arg w is harmonic in the upper half-plane v > 0 since it is the imaginary part of the analytic function g(w) = (1/) Ln w. Use this function to solve the Dirichlet problem in Fig 20.14(a).

  41. Fig 20.14

  42. Example 6 (2) Solution The analytic function f(z) = sin z maps the original region to the upper half-plane v  0 and maps the boundary segments to the segments shown in Fig 20.14(b). The harmonic function U(u, v) = (1/) Arg w satisfies the transferred boundary conditions U(u, 0) = 0 for u > 0 and U(u, 0) = 1 for u < 0.

  43. Example 7 From C-1 in Appendix IV, the analytic function maps the region outside the two open disks |z| < 1 and |z – 5/2| < ½ onto the circular region r0 |w|  1, . See Fig 20.15(a) and (b).

  44. Fig 20.15

  45. Example 7 (2) In problem 10 of Exercise 14.1, we foundis the solution to the new problem. From Theorem 20.2 we conclude that the solution to the original problem is

  46. A favorite image region R for a simply connected region R is the upper half-plane y  0. For any real number a, the complex function Ln(z – a) = loge|z – a| + i Arg(z – a)is analytic in R and is a solution to the Dirichlet problem shown in Fig 20.16.

  47. Fig 20.16

  48. It follows that the solution in R to the Dirichlet problem with is the harmonic function U(x, y) = (c0/)(Arg(z – b) – Arg(z – a))

  49. 20.3 Linear Fractional Transformations • Linear Fractional TransformationIf a, b, c, d are complex constants with ad – bc 0, then the function

  50. T is conformal at z provided  = ad – bc  0 and z  −d/c. Note when c  0, T(z) has a simple zero at z0 = −d/c, and so

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